Dynamic Effects of Turbulent Crosswind on the Serviceability State of Vibrations of a Slender Arch Bridge Including Wind-Vehicle-Bridge Interaction

The use of high-performance materials in bridges is leading to structures that are more susceptible to wind- and traffic-induced vibrations due to the reduction in the weight and the increment of the slenderness in the deck. Bridges can experience considerable vibration due to both moving vehicles and wind actions that affect the comfort of the bridge users and the driving safety. This work explored the driving safety and comfort in a very slender arch bridge under turbulent wind and vehicle actions, as well as the comfort of pedestrians. A fully coupled wind–vehicle–bridge interaction model based on the direct integration of the system of dynamics was developed. In this model, the turbulent crosswind is represented by means of aerodynamic forces acting on the vehicle and the bridge. The vehicle is modeled as a multibody system that interacts with the bridge by means of moving contacts that also simulate road-surface irregularities. A user element is presented with generality and implemented using a general-purpose finite-element software package to incorporate the aeroelastic components of the wind forces, which allows modeling and solving of the wind–vehicle–bridge interaction in the time domain without the need for using the modal superposition technique. An extensive computational analysis program is performed on the basis of a wide range of turbulent crosswind speeds. The results show that bridge vibration is significantly affected by the crosswind in terms of peak acceleration and frequency content when the crosswind intensity is significant. The crosswind has more effect on the ride comfort of the vehicle in the lateral direction and, consequently, on its safety in terms of overturning accidents.

[1]  C J Baker,et al.  Wind-induced accidents of road vehicles. , 1992, Accident; analysis and prevention.

[2]  Ragnar Sigbjörnsson,et al.  Probabilistic assessment of road vehicle safety in windy environments , 2007 .

[3]  C. Baker,et al.  A comparison of different methods to evaluate the wind induced forces on a high sided lorry , 2010 .

[4]  Daryl Boggs,et al.  Acceleration Indexes for Human Comfort in Tall Buildings—Peak or RMS? , 1997 .

[5]  K. Nguyen,et al.  Assessment of serviceability limit state of vibrations in the UHPFRC-Wild bridge through an updated FEM using vehicle-bridge interaction , 2015 .

[6]  J. D. Robson,et al.  The description of road surface roughness , 1973 .

[7]  J. D. Robson,et al.  The application of isotropy in road surface modelling , 1978 .

[8]  Suren Chen,et al.  Accident assessment of vehicles on long-span bridges in windy environments , 2004 .

[9]  Thomas J. R. Hughes,et al.  Improved numerical dissipation for time integration algorithms in structural dynamics , 1977 .

[10]  Hrvoje Jasak,et al.  A tensorial approach to computational continuum mechanics using object-oriented techniques , 1998 .

[11]  Y. Xu,et al.  Safety Analysis of Moving Road Vehicles on a Long Bridge under Crosswind , 2006 .

[12]  Charles W. Roeder,et al.  Effect of Live-Load Deflections on Steel Bridge Performance , 2004 .

[13]  Dimitris Diamantidis,et al.  The Joint Committee on Structural Safety (JCSS) Probabilistic Model Code for New and Existing Structures , 1999 .

[14]  A. Kareem,et al.  TIME DOMAIN FLUTTER AND BUFFETING RESPONSE ANALYSIS OF BRIDGES , 1999 .

[15]  Ana M. Ruiz-Teran,et al.  Serviceability limit state of vibrations in under-deck cable-stayed bridges accounting for vehicle-structure interaction , 2014 .

[16]  Suren Chen,et al.  Framework of vehicle–bridge–wind dynamic analysis , 2004 .

[17]  Hitoshi Yamada,et al.  Coupled flutter estimate of a suspension bridge , 1990 .

[18]  You-Lin Xu,et al.  Dynamic analysis of coupled road vehicle and cable-stayed bridge systems under turbulent wind , 2003 .

[19]  Jm M. Ko,et al.  Fully coupled buffeting analysis of Tsing Ma suspension bridge , 2000 .

[20]  Robert H. Scanlan,et al.  The action of flexible bridges under wind, II: Buffeting theory , 1978 .

[21]  Hassan Moghimi,et al.  Development of a numerical model for bridge-vehicle interaction and human response to traffic-induced vibration , 2008 .

[22]  Yl L. Xu,et al.  Effects of bridge motion and crosswind on ride comfort of road vehicles , 2004 .

[23]  Karl Barth,et al.  High Performance Steel: Research Front—Historical Account of Research Activities , 2004 .

[24]  Suren Chen,et al.  Fully coupled driving safety analysis of moving traffic on long-span bridges subjected to crosswind , 2015 .

[25]  G. R. Allen,et al.  Ride quality and international standard ISO 2631 (Guide for the evaluation of human exposure to whole-body vibration) , 1975 .